use crate::annotation; use crate::component::*; use crate::kw; use crate::parser::{Parse, Parser, Result}; use crate::token::Index; use crate::token::{Id, NameAnnotation, Span}; /// A parsed WebAssembly component module. #[derive(Debug)] pub struct Component<'a> { /// Where this `component` was defined pub span: Span, /// An optional identifier this component is known by pub id: Option>, /// An optional `@name` annotation for this component pub name: Option>, /// What kind of component this was parsed as. pub kind: ComponentKind<'a>, } /// The different kinds of ways to define a component. #[derive(Debug)] pub enum ComponentKind<'a> { /// A component defined in the textual s-expression format. Text(Vec>), /// A component that had its raw binary bytes defined via the `binary` /// directive. Binary(Vec<&'a [u8]>), } impl<'a> Component<'a> { /// Performs a name resolution pass on this [`Component`], resolving all /// symbolic names to indices. /// /// The WAT format contains a number of shorthands to make it easier to /// write, such as inline exports, inline imports, inline type definitions, /// etc. Additionally it allows using symbolic names such as `$foo` instead /// of using indices. This module will postprocess an AST to remove all of /// this syntactic sugar, preparing the AST for binary emission. This is /// where expansion and name resolution happens. /// /// This function will mutate the AST of this [`Component`] and replace all /// [`Index`](crate::token::Index) arguments with `Index::Num`. This will /// also expand inline exports/imports listed on fields and handle various /// other shorthands of the text format. /// /// If successful the AST was modified to be ready for binary encoding. /// /// # Errors /// /// If an error happens during resolution, such a name resolution error or /// items are found in the wrong order, then an error is returned. pub fn resolve(&mut self) -> std::result::Result<(), crate::Error> { match &mut self.kind { ComponentKind::Text(fields) => { crate::component::expand::expand(fields); } ComponentKind::Binary(_) => {} } crate::component::resolve::resolve(self) } /// Encodes this [`Component`] to its binary form. /// /// This function will take the textual representation in [`Component`] and /// perform all steps necessary to convert it to a binary WebAssembly /// component, suitable for writing to a `*.wasm` file. This function may /// internally modify the [`Component`], for example: /// /// * Name resolution is performed to ensure that `Index::Id` isn't present /// anywhere in the AST. /// /// * Inline shorthands such as imports/exports/types are all expanded to be /// dedicated fields of the component. /// /// * Component fields may be shuffled around to preserve index ordering from /// expansions. /// /// After all of this expansion has happened the component will be converted to /// its binary form and returned as a `Vec`. This is then suitable to /// hand off to other wasm runtimes and such. /// /// # Errors /// /// This function can return an error for name resolution errors and other /// expansion-related errors. pub fn encode(&mut self) -> std::result::Result, crate::Error> { self.resolve()?; Ok(crate::component::binary::encode(self)) } pub(crate) fn validate(&self, parser: Parser<'_>) -> Result<()> { let mut starts = 0; if let ComponentKind::Text(fields) = &self.kind { for item in fields.iter() { if let ComponentField::Start(_) = item { starts += 1; } } } if starts > 1 { return Err(parser.error("multiple start sections found")); } Ok(()) } } impl<'a> Parse<'a> for Component<'a> { fn parse(parser: Parser<'a>) -> Result { let _r = parser.register_annotation("custom"); let span = parser.parse::()?.0; let id = parser.parse()?; let name = parser.parse()?; let kind = if parser.peek::() { parser.parse::()?; let mut data = Vec::new(); while !parser.is_empty() { data.push(parser.parse()?); } ComponentKind::Binary(data) } else { ComponentKind::Text(ComponentField::parse_remaining(parser)?) }; Ok(Component { span, id, name, kind, }) } } /// A listing of all possible fields that can make up a WebAssembly component. #[allow(missing_docs)] #[derive(Debug)] pub enum ComponentField<'a> { CoreModule(CoreModule<'a>), CoreInstance(CoreInstance<'a>), CoreType(CoreType<'a>), Component(NestedComponent<'a>), Instance(Instance<'a>), Alias(Alias<'a>), Type(Type<'a>), CanonicalFunc(CanonicalFunc<'a>), CoreFunc(CoreFunc<'a>), // Supports inverted forms of other items Func(Func<'a>), // Supports inverted forms of other items Start(Start<'a>), Import(ComponentImport<'a>), Export(ComponentExport<'a>), Custom(Custom<'a>), } impl<'a> ComponentField<'a> { fn parse_remaining(parser: Parser<'a>) -> Result> { let mut fields = Vec::new(); while !parser.is_empty() { fields.push(parser.parens(ComponentField::parse)?); } Ok(fields) } } impl<'a> Parse<'a> for ComponentField<'a> { fn parse(parser: Parser<'a>) -> Result { if parser.peek::() { if parser.peek2::() { return Ok(Self::CoreModule(parser.parse()?)); } if parser.peek2::() { return Ok(Self::CoreInstance(parser.parse()?)); } if parser.peek2::() { return Ok(Self::CoreType(parser.parse()?)); } if parser.peek2::() { return Ok(Self::CoreFunc(parser.parse()?)); } } else { if parser.peek::() { return Ok(Self::Component(parser.parse()?)); } if parser.peek::() { return Ok(Self::Instance(parser.parse()?)); } if parser.peek::() { return Ok(Self::Alias(parser.parse()?)); } if parser.peek::() { return Ok(Self::Type(parser.parse()?)); } if parser.peek::() { return Ok(Self::Import(parser.parse()?)); } if parser.peek::() { return Ok(Self::Func(parser.parse()?)); } if parser.peek::() { return Ok(Self::Export(parser.parse()?)); } if parser.peek::() { return Ok(Self::Start(parser.parse()?)); } if parser.peek::() { return Ok(Self::Custom(parser.parse()?)); } } Err(parser.error("expected valid component field")) } } /// A function to call at instantiation time. #[derive(Debug)] pub struct Start<'a> { /// The function to call. pub func: Index<'a>, /// The arguments to pass to the function. pub args: Vec>, /// Names of the result values. pub results: Vec>>, } impl<'a> Parse<'a> for Start<'a> { fn parse(parser: Parser<'a>) -> Result { parser.parse::()?; let func = parser.parse()?; let mut args = Vec::new(); while !parser.is_empty() && !parser.peek2::() { args.push(parser.parens(|parser| parser.parse())?); } let mut results = Vec::new(); while !parser.is_empty() && parser.peek2::() { results.push(parser.parens(|parser| { parser.parse::()?; parser.parens(|parser| { parser.parse::()?; parser.parse() }) })?); } Ok(Start { func, args, results, }) } } /// A nested WebAssembly component. #[derive(Debug)] pub struct NestedComponent<'a> { /// Where this `component` was defined pub span: Span, /// An optional identifier this component is known by pub id: Option>, /// An optional `@name` annotation for this component pub name: Option>, /// If present, inline export annotations which indicate names this /// definition should be exported under. pub exports: InlineExport<'a>, /// What kind of component this was parsed as. pub kind: NestedComponentKind<'a>, } /// The different kinds of ways to define a nested component. #[derive(Debug)] pub enum NestedComponentKind<'a> { /// This is actually an inline import of a component Import { /// The information about where this is being imported from. import: InlineImport<'a>, /// The type of component being imported. ty: ComponentTypeUse<'a, ComponentType<'a>>, }, /// The component is defined inline as a local definition with its fields /// listed here. Inline(Vec>), } impl<'a> Parse<'a> for NestedComponent<'a> { fn parse(parser: Parser<'a>) -> Result { parser.depth_check()?; let span = parser.parse::()?.0; let id = parser.parse()?; let name = parser.parse()?; let exports = parser.parse()?; let kind = if let Some(import) = parser.parse()? { NestedComponentKind::Import { import, ty: parser.parse()?, } } else { let mut fields = Vec::new(); while !parser.is_empty() { fields.push(parser.parens(|p| p.parse())?); } NestedComponentKind::Inline(fields) }; Ok(NestedComponent { span, id, name, exports, kind, }) } }